Multi-reservoir feeding apparatus

ABSTRACT

A multi-reservoir feeding/dosing apparatus for the delivery of at least two substances in discrete form includes first and second conveying elements in which the discharge end thereof are a close fit in a discharge bushing thereby to ensure that the correct dosage of each substance is discharged on a consistent basis. Each conveying element is in its respective reservoir. At least one motor drives both conveying elements, with each rotational direction of the motor actuating a corresponding one of the conveying elements.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims the benefits of U.S. provisional applicationSer. No. 62/305,240, filed on Mar. 8, 2016, which is incorporated hereinby reference in its entirety.

FIELD OF THE INVENTION

The present invention relates to feeding apparatuses, and is moreparticularly concerned with such an apparatus having multiple reservoirsfor automatically, or manually, dosing powder, or granular or othersubstances in discrete form.

BACKGROUND OF THE INVENTION

It is well known in the art to provide apparatus for the delivery ofsuch materials as mentioned above at predetermined rates, namely inprescribed dosages, in for example the chemical or pharmaceuticalindustries where consistent accuracy is an important requirement fortheir processes.

Various types of dosing/feeding apparatus have been proposed and includeinter alia those employing pocketed rotors, or screw feeders in eitherthe vertical or horizontal orientations feeding particulate substancesin granular, pulverulent or generally discrete form continuously orintermittently as demanded by the relevant processes.

One of the problems attendant upon the usage of conventional apparatusis in maintaining the accuracy requirement in view of the predispositionof the driving elements to become contaminated and in so doing to affectthe quantitative performance of the apparatus on a temporal basis.Accordingly, the efficacy of the apparatus is compromised, as is theprocess for which it is being employed. Furthermore, in order to provideaccurate dosage, one must ensure that there is always feeding substanceflowing through the discharge outlet, with the space between thedischarge opening and the conveying element is substantially entirelyfilled, with no void left because of too large particle that cannotenter the space.

This is especially important when dealing with the control of theacidity level of a fluid like water of a spa, swimming pool or the like,where the feeding substance is either one of an acid or a base,depending on the actual acidity level of the fluid to be treatedrelative to the targeted level. In addition to the accurate dosage ofeither substance that is required, the available space for the feedingapparatus is usually limited.

Accordingly, there is a need for an improved dosing/feeding apparatus.

SUMMARY OF THE INVENTION

It is therefore a general object of the present invention to provide animproved dosing/feeding apparatus.

An advantage of the present invention is that the dosing/feedingapparatus provides for consistency of delivery rates in the absence ofany significant variation in quantity, for either substance.

Another advantage of the present invention is that the feeding apparatusis simple in construction and operation, with the control of eithermotor, or of the rotational direction of a motor connected to twoconveying elements referring to respective reservoirs of feedingsubstances, such as acid and base substances.

A further advantage of the present invention is that the feedingapparatus has easily replaceable parts and its adjustment is facilitatedthereby.

Still another advantage of the present invention is that the feedingapparatus provides for variations in the manner of dosage delivery.

Yet another advantage of the present invention is that the feedingapparatus is intended and capable of continuous operation, as 24 hours aday, 7 days a week.

Yet a further advantage of the present invention is that the feedingapparatus could be small in size so as to fit in tiny spaces.

According to the present invention, there is provided a multi-reservoirfeeding/dosing apparatus for feeding at least first and secondsubstances in discrete particulate form, the feeding apparatuscomprising:

a first reservoir for receiving the first substance therein and havingan inlet for the introduction of the first substance thereto and a firstoutlet for the egress of the first substance therefrom, a firstconveying element having an inlet end and a discharge end, each endbeing mounted in a respective bushing and the first conveying elementextending through the first reservoir and adapted to convey the firstsubstance in predetermined dosages from the first reservoir to the firstoutlet thereof for delivery therefrom;

a second reservoir for receiving the second substance therein and havingan inlet for the introduction of the second substance thereto and asecond outlet for the egress of the second substance therefrom, a secondconveying element having an inlet end and a discharge end, each endbeing mounted in a respective bushing and the second conveying elementextending through the second reservoir and adapted to convey the secondsubstance in predetermined dosages from the second reservoir to thesecond outlet thereof for delivery therefrom;

at least one motor operatively connected to the first and secondconveying elements; and

a controller unit operatively connecting to the at least one motor todrive the first and second conveying elements upon rotation into firstand second rotational directions, respectively.

In one embodiment, the at least one motor operatively connects to thefirst and second conveying elements via a coupling mechanism.

Conveniently, the coupling mechanism includes respective first andsecond free wheel sprockets allowing operation of the first and secondconveyor elements upon the at least one motor being operated into thefirst and second rotational directions, respectively.

Conveniently, the apparatus further includes a sensor unit connecting tothe controller unit for sensing an actual parameter level of a fluid,and the first and second outlets being in fluid communication with thefluid, and wherein the controller unit, upon the actual parameter beingsmaller or larger than a predetermined parameter level, operates the atleast one motor into the first and second rotational directions,respectively, for feeding of the first and second substances into thefluid.

Conveniently, the controller unit, depending on a difference between theactual and predetermined parameter levels, operates the at least onemotor into the first or second rotational direction for a calculatedtime duration to ensure the predetermined dosage of the first or secondsubstance into the fluid.

In one embodiment, the at least one motor includes first and secondmotors operating the first and second conveying elements, respectively.

Other objects and advantages of the present invention will becomeapparent from a careful reading of the detailed description providedherein, with appropriate reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

Further aspects and advantages of the present invention will becomebetter understood with reference to the description in association withthe following Figures, wherein:

FIG. 1 is a simplified front perspective view of a multi-reservoirfeeding/dosing apparatus in accordance with an embodiment of the presentinvention;

FIG. 2 is a sectioned top perspective view taken along line 2-2 of FIG.1, showing the inside of the apparatus;

FIG. 3 is a sectioned plan view taken along line 3-3 of FIG. 1; and

FIG. 4 is a schematic diagram of the embodiment of FIG. 1 used tocontrol parameters of the water of a spa or the like.

DETAILED DESCRIPTION OF THE INVENTION

With reference to the annexed drawings the preferred embodiments of thepresent invention will be herein described for indicative purpose and byno means as of limitation with like numerals of reference being employedfor like parts in differing embodiments of the invention or its details.

Referring first to FIG. 1, there is shown an exterior view of oneembodiment of a multi-reservoir feeding/dosing apparatus 21 including ahousing 22 encasing at least two reservoirs 32, 32′, 32 a with inletconduits 14 fed through tubes 15 from elevated hoppers 16. A receptacle18 is illustrated in ghosted outline and serves to receive doseddeliveries of at least two substances from the at least two reservoirs,the deliveries being effected by conveying elements (not shown) whichengage bushings 51 in the outlets 40, 40′ of the reservoirs 32, 32′.

Turning now to FIGS. 2 and 3 the inside of the multi-reservoir feedingapparatus 21 is illustrated. A housing 22 defines a drive chamber 23enclosing at least one motor 25 controlled in programmable fashion by aprogrammer or controller unit 24, such as using a potentiometer or thelike. The motor 25 is coupled to and is adapted to drive at least afirst conveying element 30, which extends through a first reservoir 32at the relatively lower end thereof adjacent its sloping base 33, whichis provided with a plugged drain 35. The first reservoir 32 is definedbetween two vertical compartmentalizing walls 34, 36 each of which isappropriately pierced as at 38, 40 respectively to provide a mountingzone 39, 41 for the first conveying element 30. The first conveyingelement 30 is held at each end thereof in a bushing 50, 51 providing awiping seal to give a tight fit for the drive end and the discharge endof the element. The bushings 50, 51 are held in a mounting block 52, 54respectively each of which is adjustable through the agency of a pin andslot arrangement 56 or the like securable in position by the applicationof pressure provided by wing-nuts 60 or the like. A receptacle 62 forthe reception in use of dosages of a first substance delivered by thefirst conveying element 30 through the outlet bushing 51 is locatedcontiguous with the first reservoir 32. The receptacle 62 has adischarge outlet 63 in its sloping base 65.

Similarly, the motor 25 is typically coupled to and is adapted to drivea second conveying element 30′, which extends through a second reservoir32′, essentially adjacent the first reservoir 32 and separated therefromby mid wall 37, at the relatively lower end thereof adjacent its slopingbase 33′, which is provided with a plugged drain 35′. The secondreservoir 32′ is defined between two vertical compartmentalizing walls34′, 36′ (such as extensions of walls 34, 36 respectively) each of whichis appropriately pierced as at 38′, 40′ respectively to provide amounting zone 39′, 41′ for the second conveying element 30′. The secondconveying element 30′ is held at each end thereof in a bushing 50′, 51′providing a wiping seal to give a tight fit for the drive end and thedischarge end of the element. The bushings 50′, 51′ are held in amounting block 52′, 54′ respectively each of which is adjustable throughthe agency of a pin and slot arrangement 56′ or the like securable inposition by the application of pressure provided by wing-nuts 60′ or thelike. The receptacle 62 for also the reception in use of dosages of asecond substance delivered by the second conveying element 30 throughthe outlet bushing 51′ is located contiguous with the second reservoir32′.

The first 30 and second 30′ conveying elements are each typically in theform of an auger with a scrolled flight 31, 31′ which in use serves tomove and thus convey the first and second substances within the first 32and second 32′ reservoirs through the outlets 40, 40′ to the receptacle62.

Typically, the motor 25 is coupled to the first 30 and second 30′conveying elements via a coupling mechanism 70 which includes a gear box72 coupled to respective first 74 and second 74′ free wheel sprocketsallowing operation of the first 30 and second 30′ conveyor elements uponthe motor 25 being operated into first and second rotational directions,respectively, as illustrated in FIG. 3.

As shown in FIG. 4, the apparatus 21 can include at least one sensorunit 80 connected to the controller unit 24 for sensing a correspondingactual parameter level of a fluid, as water in a spa 90 or the like,being in fluid communication with the discharge outlet 63 along a fluidcirculation conduit 92 including usual fluid pump 94, filter 96, andheater 98.

In operation, first and second substances in discrete form, for examplepowder or granules, could be held in hoppers 6 and gravitationally feedthrough the tubes 5 into the reservoirs 32, 32′ where the substances aresupported by the sloping bases 33, 33′ and between the walls 34, 36 and34′, 36′. Actuation of the motor 25, in either rotational direction, inaccordance with a programmed dosing regime on a temporal basis, e.g.g/min, g/hr, is instigated with the result that the correspondingconveying element 30, 30′ rotates and in so doing its flight 31, 31′picks up the corresponding substance and scrolls it towards the outletbushing 51, 51′. It will be understood by the skilled addressee thatsince the auger lies and rotates within the body of the substance in thecorresponding reservoir 32, 32′, the outer surface of the flight 31, 31′is in contact with that substance and may attract particles which arecarried thereby towards the outlet bushing 51, 51′. However, in view ofthe tight fit of the discharge end of the conveying element 30, 30′within its bushing 51, 51′, the particles so attracted are in effectbarred from entering the outlet bushing 51, 51′ and thus thepredetermined dosage maintains its accuracy since it is not contaminatedby inadvertent carriage of particle adhering to the outer surface of thescroll flight 31, 31′.

The substance discharged through the outlet bushing 51, 51′ descends asillustrated in FIG. 3 into the receptacle 62 onto the sloping base 65and falls through the discharge outlet 63 for predestined use in arelevant process which could be for example chemical or pharmaceuticalin character, such as the two substances being an acid and a basesubstance used to control the acidity or pH level of a fluid (as thewater of a spa or the like), since at each time, either one of the twosubstances need to be fed.

To this end, the controller unit 24, upon the actual parameter sensedfrom the sensor unit 80 being smaller or larger than a predeterminedparameter level, operates the motor 25 into the first or secondrotational direction, respectively, for feeding of the first or secondsubstances into the fluid. Similarly, the controller unit 24, dependingon a difference between the actual and predetermined parameter levels,operates the motor 25 into the first or second rotational direction fora calculated time duration, or a calculated rotational angle of theconveying element 30, 30′ to ensure the predetermined dosage of thefirst or second substance is fed into the fluid.

Although the feeding/dosing apparatus could be deployed for thecontrolled feeding of animals and such application may be particularlyuseful for intensive farming, where regular and closely monitored andaccurate feeding of the animals is necessary, similarly to the feedingof chemical nature as for the acidity level control of the water of aspa, swimming pool or the like. The programming of the motor operationmay not only dictate the volume of the feed, but also the duration andnumber of times the motor is actuated.

Although not illustrated herein, it would be obvious to one skilled inthe art, without departing from the scope of the present invention, tohave one motor 25, 25′ per conveying element 30, 30′. Similarly, the tworeservoirs 32, 32′, instead of being positioned side-to-side (as shown),they could be positioned back-to-back with the two conveying elements30, 30′ being co-axial relative to one another, or even being a sameelement, but having reverse threads or flights 31, 31′ such that,depending on the rotational direction of the conveying element 30, 30′,either one of the first and second substances is fed. In such a case,when precise feeding is required, the controller unit 24 may have toaccount for an additional rotational angle due to a ‘reset’ of thecorresponding feeding element (before it will actually start deliveringthe corresponding substance) when the previous feeding was for the othersubstance (in the reverse rotational direction which induced a back-offof the substance ready for being delivered).

Although partially illustrated in FIG. 1 in stippled lines, more thanthe two reservoirs 32, 32′ can be considered without departing the scopeof the present invention. Each of these additional reservoirs 32 a, forexample, has its own conveying element with its drive motor for feedinga corresponding substance into the fluid. Additional correspondingsensors, sensing respective parameters of the fluid, connected to thecontroller unit 24 could determine the need to feed the correspondingsubstance, and the specific required amount thereof, into the fluid.

Although the present invention of a multi-reservoir feeding/dosingapparatus has been described with a certain degree of particularity, itis to be understood that the disclosure has been made by way of exampleonly and that the present invention is not limited to the features ofthe embodiments described and illustrated herein, but includes allvariations and modifications within the scope and spirit of theinvention as hereinafter claimed.

1. A feeding apparatus for feeding at least first and second substancesin discrete particulate form, the feeding apparatus comprising: a firstreservoir for receiving the first substance therein and having an inletfor the introduction of the first substance thereto and a first outletfor the egress of the first substance therefrom, a first conveyingelement having an inlet end and a discharge end, each end being mountedin a respective bushing and the first conveying element extendingthrough the first reservoir and adapted to convey the first substance inpredetermined dosages from the first reservoir to the first outletthereof for delivery therefrom; a second reservoir for receiving thesecond substance therein and having an inlet for the introduction of thesecond substance thereto and a second outlet for the egress of thesecond substance therefrom, a second conveying element having an inletend and a discharge end, each end being mounted in a respective bushingand the second conveying element extending through the second reservoirand adapted to convey the second substance in predetermined dosages fromthe second reservoir to the second outlet thereof for deliverytherefrom; at least one motor operatively connected to the first andsecond conveying elements; and a controller unit operatively connectingto the at least one motor to drive the first and second conveyingelements upon rotation into first and second rotational directions,respectively.
 2. A feeding apparatus as claimed in claim 1, wherein theat least one motor operatively connects to the first and secondconveying elements via a coupling mechanism.
 3. A feeding apparatus asclaimed in claim 2, wherein the coupling mechanism includes respectivefirst and second free wheel sprockets allowing operation of the firstand second conveyor elements upon the at least one motor being operatedinto the first and second rotational directions, respectively.
 4. Afeeding apparatus as claimed in claim 3, further including a sensor unitconnecting to the controller unit for sensing an actual parameter levelof a fluid, and the first and second outlets being in fluidcommunication with the fluid, and wherein the controller unit, upon theactual parameter being smaller or larger than a predetermined parameterlevel, operates the at least one motor into the first and secondrotational directions, respectively, for feeding of the first and secondsubstances into the fluid.
 5. A feeding apparatus as claimed in claim 4,the controller unit, depending on a difference between the actual andpredetermined parameter levels, operates the at least one motor into thefirst or second rotational direction for a calculated time duration toensure the predetermined dosage of the first or second substance intothe fluid.
 6. A feeding apparatus as claimed in claim 1, wherein the atleast one motor includes first and second motors operating the first andsecond conveying elements, respectively.